SE523698C2 - Method and apparatus for non-invasive measurement of transcutaneous oxygen uptake - Google Patents

Abstract

A method for noninvasive measuring of transcutaneous oxygen uptake from ambient air, comprising the steps: shielding (2) an area of skin (1) to be examined from air currents to provide a stable boundary layer (6), sensing (4, 5) the partial pressure of the oxygen in at least two different points positioned on at least two different heights from the skin surface (1) within the stable boundary layer (6) outside the skin surface (1), apply the equation (I) where A is the area, m is the amount of oxygen, dp/dx is the gradient for the partial pressure of oxygen and DOL is the diffusion constant for oxygen in air, so that the gradient of the partial pressure of oxygen in the boundary layer (6) is calculated; and an apparatus for performing the method.

Description

W B 20 25 30 35 40 523 693 - q -sno v In practice, it is difficult to apply a transcutaneous oxygen pressure monitor to a leg ulcer or damaged tissue and thus it is difficult to obtain any interpretation of the oxygen status in the tissue. When possible (intact skin), the skin needs to be heated to be able to register the partial pressure of oxygen. However, this does not reflect the undisturbed ratio as the heating involves changes in the undisturbed ratio.

In many cases where transcutaneous monitoring has been performed, very low values are recorded despite the fact that the tissue apparently survives. This is probably due to the fact that the recorded partial oxygen pressure is not correlated to the oxygen consumption in the tissue during examination under an undisturbed condition.

An attempt to improve transcutaneous monitoring is shown in US 5,376,336. The document discloses a device having a sensor block defining opposite first and second sensor layers, the first sensor layer being positioned against the skin and having a luminescence optical indicator embedded in the sensor layer. On the opposite sides of the sensor block, the second sensor layer is arranged. The sensor bearings have a known or predetermined resistance to the material flow to be measured.

In an embodiment specially made for sensing oxygen flow, the second sensor layer is excluded because the inventors are of the opinion that the partial pressure of oxygen is constant in ambient air. The sensor is preferably controlled by a thermostat and a gas-tight cup is preferably arranged over the sensor to prevent the gas flow.

A problem with the transcutaneous sensor in US 5,376,336 is that it cannot reflect the true undisturbed oxygen uptake of the skin from ambient air. This is due to the fact that the sensor block is attached to and against the skin area to be measured, either by means of an adhesive or vacuum. This is still more W U 20 25 30 35 40 525 693 3. - I '. "' I true when a gas-tight cup is used and / or the skin area is heated by the thermostat, whereby the skin perfusion is arterialized.

Another problem is that the sensor layer must be positioned against the skin to be examined. This is an undesirable feature, especially when the examined area is a wound, burnt skin or leg ulcer, as there is an increased risk of introducing bacteria and other unwanted substances into the sensitive area to be examined.

SUMMARY OF THE PRESENT INVENTION An object of the present invention is to provide a method and apparatus for non-invasive measurement of the transcutaneous oxygen uptake from ambient air.

This is accomplished by a method and apparatus in accordance with the following two independent claims.

By means of this method and device, it is possible to measure the correct oxygen uptake in the skin or any other oxygen-consuming tissue or material from ambient air, since the area to be examined is not disturbed by a sensor layer attached to the area. Due to the open sensor screen, the area to be examined is protected from disturbing circulating air currents so that the near zone becomes stable.

Measurement will take place without any contact with the skin or any disturbing material at the site of measurement. It is in its natural environment without the addition of anything and the sensors will not consume any gas to be measured.

For the first time, it is possible to determine the correct oxygen consumption of a skin area exposed to ambient air.

In the absence of forced convection, the human body is surrounded by a near zone that has a thickness of 7-10 mm, which forms a physical barrier to the environment. This zone is a transition zone or diffusion zone for the exchange of gases between the body and the surrounding air.

W ß 20 25 30 35 40 525 698 Tests have been performed in the outer skin layer with microelectrodes to measure the partial pressure of oxygen in the tissue. These tests have shown that a negative profile of the partial pressure of oxygen exists in the outer skin layer and that this actively forces oxygen molecules from ambient air through the outer skin layer for consumption in the underlying tissue layers.

Since the gradient of the partial pressure of oxygen is negative from the skin surface and inwards into the tissue, this means that oxygen molecules diffuse through the skin surface into the tissue. At a particular point, this gradient turns into a positive gradient, which means that oxygen is also fed to the tissue from the inside, via the circulation, to the oxygen-consuming skin area.

With knowledge of these gradients and the diffusion constant for oxygen in tissue, the inventor realized that the amount of oxygen transported (and consumed) can be calculated according to the form: l ä = -Dovd_P A dt dx where A = the area, m = the amount of oxygen, Dm, = the diffusion constant for oxygen in tissue and dp / dx is the gradient of the partial pressure of oxygen.

For this reason and due to the continuity equation and the presence of a near zone surrounding the body surface, the amount of oxygen penetrating the skin surface may also be shown to be proportional to the gradient of oxygen partial pressure at this near zone and described as: dm = 'DOLgB l A dt dx where D for oxygen in air. 10 15 20 25 30 35 523 698 n 0 f n. a | 1 1 of n q n o | o 0 a n 0 a u o u nu a | 1 1 q n fu n ~ -nano- n. n o 0 n av -_ ua 5 Since oxygen is not produced nor consumed in the near zone, both the oxygen flow rate and thus the gradient of the oxygen partial pressure are constant. The amount of oxygen can be measured by measuring the gradient or estimating this gradient by measuring the partial pressure of the oxygen at at least two points within the near zone at different levels from the skin surface. By shielding the area to be examined, the near zone is protected from adverse effects by circulating air currents.

The sensors used in measuring the partial pressure of oxygen are freely arranged in the volume defined by the shielded area of the near zone, i.e. not arranged in any material that blocks the natural diffusion.

The device according to the present invention provides a measure of how much oxygen a tissue can absorb from ambient air and how much this amount of oxygen contributes to the total consumption of oxygen in the tissue, which also includes a component supplied by the microvascular system.

Furthermore, it is also possible to calculate the partial pressure of oxygen at the skin surface by starting from the linear decrease of the partial pressure of oxygen near the skin surface and extrapolating the partial pressure of oxygen at the skin surface.

Brief Description of the Drawing The present invention will now be described by way of example with an embodiment of an apparatus in accordance with the present invention taken in conjunction with a drawing, in which: Fig. 1 illustrates the principle of a measuring method and apparatus in accordance with the present invention.

Fig. 2 illustrates a further embodiment of the method and device according to Fig. 1.

Fig. 3 shows an embodiment of a device in accordance with the present invention.

Detailed Description of Preferred Embodiments Figure 1 shows an area of a skin surface 1 partially shielded by a screen 2 for measuring the flow rate of oxygen 3 into the skin 1. The measurement takes place and the device is positioned in the proximity zone 6 above the skin surface 1. At least two sensors for sensing the partial pressure of oxygen, an upper sensor 4 and a lower sensor 5, are arranged in a volume 9 defined by the screen 2 and the proximity zone 6.

In Fig. 2, a thermistor 7 is arranged in the volume 9 for measuring the temperature.

Fig. 3 shows an embodiment of a device in accordance with the present invention. The device comprises a hand-held probe 8 provided with a screen 2 within which an upper 4 and a lower sensor for the partial pressure of oxygen are freely arranged, i.e. not arranged in any material that blocks the natural diffusion. The hand-held probe 8 is connected to a measuring instrument (not shown) comprising means for evaluating the sensed measurements in accordance with the equation lill = "DOLÉE A dt dx The means for evaluating calculates the gradient of the partial pressure of oxygen and the amount of oxygen taken up by the tissue through the skin surface. .

The screen 2 is open downwards towards the area 1 to be examined and upwards towards the ambient air, similar to a chimney. To achieve as reliable results as possible, the height of the screen 2 should be of the same height as the near zone 6, ie 7-10 mm. Preferably, the screen 2 is removable and made of a material which is 10 15 20 25 35 523 693 š¶? .¿¿, ¿_ 7 u. '»' U '~ suitable for disinfection in any suitable way. The screen 2 can be open in the side wall for connection to the hand-held probe 8.

The sensors 4, 5 for measuring the partial pressure of oxygen could be fluorescence-based optical sensors, for example FOXY Fiber Optical Oxygen Sensor from Ocean Optics Inc.

The operating principle of the preferred sensors is based on dynamic "fluorescence quenching response" on the partial pressure of oxygen. The tip of an optical fiber is provided with fluorescent material which emits light of a different wavelength than what it is illuminated with in the presence of oxygen. Either the same optical fiber or a second optical fiber transmits the emitted light to the measuring instrument. The sensor preferably has a response time of less than one second. The life of the sensor without calibration is preferably one year.

These sensors 4, 5 do not consume any oxygen. The upper sensor 4 is arranged further away in a vertical direction from the skin surface 1 than the lower sensor 5, but both are arranged within the proximity zone 6 and closer to the skin surface 1 than the upper edge 10 of the screen 2. The upper 4 and lower 5 sensor need not be arranged vertically above each other but may be horizontally offset from each other. An alternative sensor for the partial pressure of oxygen is a platinum electrode, also called a Clark electrode, but this sensor has the disadvantage that it consumes oxygen.

The diffusion constant for oxygen in air may be slightly dependent on temperature. Thus, the use of a thermistor 7 will increase the reliability of the result. Preferably, the thermistor 7 is arranged between the two sensors 4, 5 and will measure the temperature and, when necessary, compensate for the temperature in the area 1 to be examined. The device of the present invention could be used, for example, in the evaluation of wounds, leg ulcers, peripheral vascular disease, poor blood supply to the legs, hyperbaric medicine, burns, etc. Another use is to evaluate the function of the oxygen barrier in, for example, artificial skin.

Claims (5)

10 15 20 25 30 35: Zïzïí fi 9 | n n o u .n PATENT REQUIREMENTS Device for non-invasive measurement of transcutaneous oxygen uptake from ambient air, characterized by a hand-held probe (8) provided with a screen for shielding an area of the skin (1) to be examined from air currents to provide a stable near zone (6 ), that at least one upper (4) and one lower (5) sensor for sensing the partial pressure of oxygen are freely arranged inside the screen (2) at at least two different heights from the skin surface (1) inside the stable proximity zone (6), the hand-held the probe (8) is connected to a measuring instrument comprising means for evaluating the sensed measurements in accordance with the equation lë = -DOLÉB A dt dx where A is the range, m is the amount of oxygen, dp / dx is the gradient of the partial pressure of oxygen and Dm, is the diffusion constant for oxygen in air, and the gradient of the partial pressure of oxygen and the amount of oxygen taken up by the tissue through the skin surface (1) are calculated by the means for evaluation. Device according to claim 1, in which a thermistor (7) for measuring the temperature is arranged inside the volume (9) defined by the screen (2) and the proximity zone (6). Device according to claim 1 or 2, in which the sensors (4, 5) are fluorescence-based optical sensors. Device according to claims 1, 2 and 3, in which the screen (2) is open downwards towards the area (1) to be examined and upwards towards ambient air. 5 2 5 6 9 8 = "rf. L n a n u u | oo 10 Device according to one of the preceding claims, in which the screen (8). (2) is removable from the handheld probe